ES2644767T5 - Membrane and procedure for its manufacture - Google Patents

Description

DESCRIPTION

Membrane and procedure for its manufacture

The invention relates to a membrane, in which the membrane is made up of several layers, and in which at least one of the layers is made of an elastomer.

Such a membrane is generally known. In this case, membrane data is often printed or stamped on the membrane.

The invention also relates to a process for the manufacture of the membrane.

Document US 2008/020178 A1 discloses a typical membrane, which is made up of several layers and is at least partially made of an elastomer, and which has a membrane surface as a functional zone.

From document US 2005/189408 A1 a conventional sealing ring is known, consisting of several layers, in which an RFID chip is arranged between two layers.

In the same way, a sealing element is deduced from EP 2242004 A1, in which a data carrier is housed within a connection zone.

The problem of the invention is to improve the known membrane in particular with regard to data association. In the membrane mentioned at the beginning, this problem is solved by means of the characteristic features of claim 1.

By using an electronic data carrier, the possibility of associating data to the membrane is expanded almost unlimitedly. Thus, for example, not only data relating to materials, dimensions, manufacture and similar characteristic variables of the membrane can be recorded on the data carrier, but also data relating to the respective customers, the supply, etc. In this case, all these data can be aligned on the respective individual membrane and recorded on its respective data carrier.

By wrapping the data carrier by the membrane layers and the upper layer and the lower layer, protection of the data carrier against environmental influences as well as protection against the operating environment of the membrane is achieved. Especially oils or dirt or the like have no influence on the readability of data from the data carrier.

According to the invention, the membrane is provided with a flange, which projects beyond the surface of the membrane, and in which the data carrier is arranged on the flange.

Through the projection of the flange on the surface of the membrane and, therefore, on the functional area of the membrane as well as by virtue of the arrangement of the data carrier on the flange, it is achieved that a reading device can be installed In the environment of the data carrier and with the reader device, data can be read from the data carrier. In particular in this way it can be achieved that, for example, parts of the housing, between which the membrane is formed, do not have only a small influence on the location of the reading device or on the readability of the data.

In one embodiment of the invention, an RFID-Chip (RFID = radio frequency identification) is present as the data carrier. Preferably, the RFID-Chip is configured in the shape of a disk. In this case, it is advantageous that a surface of the disc of the RFID-Chip is aligned in a plane approximately parallel to the surface of the membrane. An antenna is often present in the RFID-Chip in the region of its disk surfaces. By means of the approximately parallel alignment of the surface of the disk with respect to the surface of the membrane, it is achieved that the reading device can be associated particularly well with the antenna of the RFID-Chip. In this way, the reading of data from the data carrier is improved.

In the process for producing the membrane, provision is made for the bag to be cut out as a recess in the respective materials of the individual layers. If the overlapping membrane layers are subsequently formed, the data carrier pocket is thus created. The data carrier can then be inserted into this bag and vulcanized together with the overlapping formed layers of the membrane.

It is particularly expedient if a tool, in particular a forming nest, is used for the formation of the individual layers. In this way a stable arrangement in the position of the layers can be achieved.

Other characteristics, application possibilities and advantages of the invention are deduced from the following description of embodiments of the invention, which are represented in the corresponding figures. In this case, all the features described or represented, by themselves or in a discretionary combination, are the object of the invention, which is only limited by the scope of protection of the appended patent claims.

Figure 1 shows a schematic perspective view of an embodiment of a membrane according to the invention, Figures 2a, 2b, 2c show a top plan view, a side view and a front view of the membrane of the figure 1, figure 3 shows a perspective view of fragment A of figure 1, and figure 4 shows a perspective view of a bag present in the membrane of figure 1.

In Figures 1 to 4, a diaphragm 10 is shown that can be used in a valve, for example a pneumatically, hydraulically or electrically actuated diaphragm valve. The membrane 10 has an approximately rectangular membrane surface in plan view and has an essentially constant membrane thickness transversely to the membrane surface.

It is understood that the membrane 10 can also have a geometric shape configured in another way. For example, the membrane 10 can also be shaped round.

An approximately rectangular membrane surface represents the functional zone of the membrane 10. Approximately in this functional zone, the membrane 10 is formed with the corresponding valve. For example, the membrane 10 may be arranged within the functional zone between two parts of the corresponding valve housing.

On one of the longitudinal sides, the membrane 10 provides a flange 12. In the present exemplary embodiment, the flange 12 is configured as an approximately rectangular projection, which projects onto the surface of the approximately rectangular membrane. The dimensions of the flange 12, in particular the extension of the flange 12 approximately transverse to the corresponding longitudinal side of the membrane 10, are selected in this case in such a way that the flange 12 projects, if possible, also onto parts of the given housing. the present case of the corresponding valve.

It is understood that the flange 12 can also have a geometric shape of another type.

The membrane 10 with the flange 12 is made up of a plurality of layers, in which each of the individual layers can be made of an elastomer or of a fabric or of a stabilizing layer or the like, and in which the elastomers or the fabrics of the different layers can be made respectively of different materials, for example rubber or silicone or the like.

On the flange 12 a bag 14 is present. Reference is made here to FIG. 4. The bag 14 is arranged approximately centrally within the approximately rectangular flange 12. In the present embodiment, the bag 14 is configured approximately circularly, so that the axis of the bag 14 is aligned approximately transverse to the surface formed by the flange 12. The bag 14 has a depth in the axial direction, which is less than the thickness of the membrane.

An electronic data carrier 16 is housed in the bag 14. Reference is made here to FIG. 3. The data carrier 16 is approximately disk-shaped and has a thickness in the axial direction. The dimensions of the bag 14 and of the data carrier 16 are adapted to each other in such a way that the data carrier 16 can be inserted into the bag 14 during the manufacture of the membrane 10.

It goes without saying that the data carrier 16 can also have a geometric shape configured in another way. The bag 14 is then adapted thereto in a corresponding way.

The data carrier 16 can either project after insertion into the bag 14 over the bag 14, as indicated in FIG. 3, or it can also be housed without a projection on the bag 14.

The data carrier 16 can be any electronic component, from which data can be recorded and can be read out again. In particular, the data carrier 16 can be a so-called RFID-chip (RFID = radio frequency identification), which normally has a transponder, on which data can be entered, which can be read by a reader with the help of electric waves.

The bag 14 is closed in the finished manufactured state of the membrane 10 on its lower side and on its upper side. In the present exemplary embodiment, this is achieved by means of an upper layer 18 as well as a lower layer 19. These two layers 18, 19 form the lowest layer and the highest layer of the membrane 10 and of the flange 12.

In the finished manufactured state of the membrane 10, the data carrier 16 is thus embedded in the flange 12. In particular, the data carrier 16 is surrounded by the material of the layers of the flange 12 as well as by the layer upper and lower layer 18, 19. The data carrier 16 is thus completely contained within the material layers as well as the upper layer and the lower layer of the membrane 10.

Access from the outside to the data carrier 16 is not present and a replacement of the data carrier 16 is also not possible without a destruction of the explained embedding of the data carrier 16 in the flange 12. Figures 1 to 3 show the upper layer 18 for the purpose of representation in the area of the flange 14 approximately transverse distance from the membrane 10. It is indicated that the layer 18 in the manufactured state The finished membrane is not actually spaced transversely, but is aligned flat also in the flange area and is thus superficially connected to the underlying layer of the membrane 10. The bag 14 is thus covered by the layer 18 and closes, as mentioned.

The data carrier 16 is contained in this way in the flange 12 and is surrounded by the material of the flange 12. The flange 12 in this case protrudes over the functional area of the membrane 10.

As explained, the axis of the bag 14 and, therefore, of the data carrier 16 in the present exemplary embodiment is aligned approximately transversely to the surface formed by the flange 12. In this way, the upper and lower surface of the data carrier disk 16 in the present exemplary embodiment is in a plane approximately parallel to the surface of the membrane. If an antenna is often arranged in the region of the upper and lower surface of the disk, especially in the case of an RFID-chip, it is possible to install a reading device above it in the assembled state of the membrane 10. or below the flange 12 and thus directly on the surface of the disk of the data carrier 16 and then read the data.

Alternatively, it is also possible that the data carrier 16 with its disk surface is arranged in another way within the flange 12. For example, it is possible that the disk surface of the data carrier 16 extends approximately parallel to the side. front longitudinal side of the flange 12. In this case, in the assembled state of the membrane 10, it is possible to place a reading device in front of the front longitudinal side of the flange 12 and thus in front of the disk surface of the data carrier. 16 and then read data carrier 16.

It is alternatively possible that a data carrier is used, which has a different shape than that shown in Figures 1 to 3. For example, it can be rectangular or oval. In these cases, the data carrier can be arranged again within the flange in such a way that a reading device can be positioned as close as possible to an antenna of the data carrier.

Depending on the configuration of the flange 12 as well as the shape of the data carrier 16 or the arrangement of an antenna within the data carrier 16, an optimal position and arrangement of the data carrier 16 within the data carrier 16 can be achieved. tab 12 regarding the best possible reception conditions.

A possible method for manufacturing the membrane 10 is explained below.

As explained, the membrane 10 and the flange 12 are made up of several layers. The desired outer contour of membrane 10 with flange 12 is first cut out from the respective materials of the individual layers. For example, this outer contour is stamped from the intended elastomer (s) as well as from the intended fabric material (s). In this case, the bag 14 is taken into account in the same way in the flange 12 and is cut out from the recess of the respective material.

Correspondingly, the upper layer and the lower layer 18, 19 are also cut out from the material provided, so that there are no cut-outs for the bag 14 here.

The individual cut layers of membrane 10 and flange 12 are then formed successively in the desired sequence and introduced into a tool, in particular a forming nest. Within the framework of these measures, in particular before the application of the upper layer 18 on the underlying layers of the membrane 10, the data carrier 16 is inserted into the bag 14.

The structure of the layers of the membrane 10 present in the tool is then vulcanized together with the data carrier 16 contained therein.

If the data carrier 16, as mentioned, protrudes above the bag 14, then this protrusion is compensated during the mentioned vulcanization of the membrane 10. For example, it is possible that the protrusion of the data carrier 16 is introduced to pressure on the corresponding layer 18, 19.

For the purpose of adjusting the successively cut layers, it is possible that a cylindrical component is inserted into the recesses of the individual layers that form the bag 14. This component can either be removed again after the formation of the entire membrane 10 or it can also remain on the membrane 10, in this case inserting the data carrier 16 then into the cylindrical component.

It is understood that other manufacturing processes are also conceivable for the membrane 10 and the flange 12. The process according to the invention is only limited by the features of claim 5.

Claims (6)

1 Membrane (10) for a membrane valve, in which the membrane (10) is made up of several layers and in which at least one of the layers is made of an elastomer, in which the membrane (10) has a upper layer and a lower layer (18, 19), and in which the membrane (10) has a membrane surface, which represents the functional zone of the membrane (10), characterized in that the membrane (10) is provided with a flange (12), which projects beyond the surface of the membrane, because an electronic data carrier (16) is arranged on the flange, and because the data carrier (16) is surrounded by layers of the membrane (10) and by the upper layer and the lower layer (18, 19). 2. - Membrane (10) according to claim 1, in which the data carrier (16) is a Chip-RFID (RFID = radio frequency identification). 3. - Membrane (10) according to claim 2, in which the RFID-Chip is configured in the form of a disk. 4. - Membrane (10) according to claim 3, in which a disk surface of the RFID-Chip is aligned in a plane approximately parallel to the surface of the membrane. 5. - Procedure for the manufacture of the membrane (10) according to one of the preceding claims with the following steps: the outer contour of the membrane (10) and the flange (12) is cut from the respective materials of the individual layers, a pocket (14) is cut out as a notch in the respective materials of the individual layers, the outer contour of the membrane (10) and flange (12) is cut out from the top layer and the bottom layer (18, 19), the individual overlapping cut layers are formed, the data carrier (16) is inserted into the bag (14), the structure of the membrane layers (10) is vulcanized with the data carrier (16) contained in it. 6. - Method according to claim 5, in which a tool is used for the formation of the individual cut layers, in particular a formation nest.